CN104944767B - High-refractive and high-dispersive optical glass - Google Patents
High-refractive and high-dispersive optical glass Download PDFInfo
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Abstract
The present invention provides a kind of blue light transmitance excellent high-refractive and high-dispersive optical glass, and its refractive index is 1.73 1.88, and Abbe number is 25 32.High-refractive and high-dispersive optical glass, represented, contained with weight percent oxide:SiO2:20‑35%、B2O3:1‑7%、TiO2:20‑35%、La2O3:1‑10%、ZrO2:0.5‑6%、Y2O3:0.5‑8%、BaO:18‑38%、K2O:0.5‑5.5%、Na2O:3 10%, do not contain Nb2O5.The high-refractive and high-dispersive optical glass liquidus temperature of the present invention is less than 1100 DEG C, and λ 80 is in below 450nm, and surface devitrification resistance can be more than B levels, and internal devitrification resistance can be A levels, powder method acid-resistant stability DAFor 1 grade, powder method water-resistant stability DWFor 1 grade.
Description
Technical field
The present invention relates to a kind of lanthanum flint glass of high-refraction high-dispersion, its ranges of indices of refraction is 1.73-1.88, Abbe number
Scope is 25-32.
Background technology
The glass that ranges of indices of refraction is 1.73-1.88, Abbe number scope is 25-32 belongs to high-refraction high-dispersion glass, this
Kind material is applied than wide in contemporary optics design.Compared with the low refractive optics glass of in general, high index of refraction optics glass
Glass can shorten the image-forming range of camera lens so that the imaging such as card camera, slr camera, monitoring camera, vehicle-mounted pick-up camera lens is set
For while larger numerical aperture is ensured, the volume of imaging device can be reduced.In addition, high-dispersive optical glass and low color
Dispersion optical glass coupling uses, and can solve aberration, difference etc. to being imaged unfavorable factor, lift image quality.Meanwhile Yi Zhongguang
Whether glass is excellent to also need to consider λ 80(I.e. glass transmitance reaches corresponding wavelength when 80%), chemical stability, resistance to mistake
The factors such as permeability energy, processing performance and cost.
The indexs of optical glass λ 80 mainly consider optical glass in blue ray wave band, i.e. 380-450nm wave-length coverages
Transmitance, in general optical design, the numerical value of λ 80 is lower, and it is higher to represent blue wave band transmitance;λ 80 numerical value is got over
Height, the transmitance for representing blue wave band are lower.In optical design, if material is insufficient in the transmitance of hyacinthine wave band, that
The hyacinthine light of image-forming component, such as CCD, COMS reception will lack compared with other wavelength light, the photographic quality so obtained
Distortion will occur.Especially for more lens optical systems, such as slr camera, its piece eyeglass of optical routing more than 10 is formed, if
The λ 80 of every eyeglass is too high, then the hyacinthine wave band light that can finally reach image-forming component will less very relative to its all band
It is more, can so cause shooting photographic quality distortion, so more lens optical systems for requirement it is just higher.
In general, high refractive optics glass is in order to reach higher refractive index, the SiO in its component2、B2O3Deng network
It is fewer to form body, and adds more TiO2、WO3、Nb2O5Contour refraction oxide.The addition of these height refraction oxides
The light of hyacinthine wave band can be absorbed so that glass λ 80 rises.So in optical glass field, how high index is obtained
While and can to obtain relatively low λ 80 be a problem persistently studied.For such glass, λ 80 except by glass in itself
Beyond components influence, also had a great influence by smelting technology.In general, relatively low smelting temperature can obtain preferable λ 80,
For the glass of titaniferous, its λ 80 is influenceed bigger by technique.This requires Glass Design, and person is designing glass group
Timesharing will consider the problem of glass technology, i.e., to reduce the liquidus temperature of glass, enable to carry out at a lower temperature
Melting.
From the perspective of optical manufacturing, the devitrification resistance of optical glass having high refractive index is also to weigh a kind of optical glass
Important indicator.The processing of optical mirror slip is divided into two kinds of cold working and hot pressing type.Cold working refers to glass processing with instrument into institute
The blank needed, then it is ground, polishes.Hot pressing type refers to glass-cutting to be then placed in into block blank in mould
Heating, required shape is pressed into after Glass Transition.If using precision die die mould, the glass suppressed even can be with
Without processes such as grinding, polishings, can directly install use.So compared with cold working, hot pressing type technique manufacture optical frames
Piece has the advantages that few wastage of material, efficiency high, cost are low, environmental pollution is few.But for high refractive optics glass, by
Relatively low in its Network former content, easy crystallization, causes yields to decline in hot pressing type technique.
High-refraction high-dispersion glass generally passes through Nb2O5、WO3、Ta2O5、TiO2Improved Deng high-refraction high-dispersion oxide
The refractive index of glass and dispersion.Consider from cost of material, Ta2O5Price highest, Nb2O5And WO3Take second place, TiO2Price most
It is low, TiO2Price be about Ta2O51/100, about Nb2O5And WO31/10.By measuring and calculating, often increase in such glass ingredient
Add weight is 1% Ta2O5, then the cost of material of glass will lift 90-100% or so.As often increased by 1% in fruit component
Nb2O5Or WO3, then the cost of material of glass will rise 12-15% or so.In addition, for the scarcity of raw material,
Ta2O5、Nb2O5And WO3Rare oxide is belonged to, it is very extensive in chemical industry, electronics industry application.Meanwhile these are provided
Source needs to expend a large amount of manpowers and the energy and exploited and deep processing, and larger pollution is unavoidably produced to environment.Existing
In technology, such glass works as TiO2When addition is more than 12%, the blue light transmitance of glass will be seriously reduced.So ensureing
While the values of λ 80 meet optical design, how research increases TiO2Content in high refracting glass, reduce Ta2O5、Nb2O5、
WO3Etc. the consumption of rare oxide, sound development, reduction resource consumption to optical glass industry have important meaning.
TiO in optical glass disclosed in Chinese patent application 201310010806.42Content is less, and containing more
Nb2O5And WO3, and its λ 70(Glass transmitance reaches corresponding wavelength when 70%)440nm or so is can only achieve, this is for more
The design of lens imaging subsystem is unfavorable.
The content of the invention
The technical problems to be solved by the invention are to provide a kind of excellent high-refractive and high-dispersive optical glass of blue light transmitance
Glass, its refractive index are 1.73-1.88, Abbe number 25-32.
The technical proposal for solving the technical problem of the invention is:High-refractive and high-dispersive optical glass, with oxide weight
Measure percentage to represent, contain:SiO2:20-35%、B2O3:1-7%、TiO2:20-35%、La2O3:1-10%、ZrO2:0.5-6%、
Y2O3:0.5-8%、BaO:18-38%、K2O:0.5-5.5%、Na2O:3-10%, Nb is not contained2O5。
Further, total content of the oxide is more than 95%.
Further, Gd is also contained2O3:0-8%、ZnO:0-6%、CaO:0-5%、SrO:0-5%、Li2O:0-2%、MgO:0-
5%。
Further, wherein:SiO2:22-31%.
Further, wherein:B2O3:2-6%.
Further, wherein:TiO2:21-31%.
Further, wherein:La2O3:2-8%.
Further, wherein:ZrO2:0.5-5%.
Further, wherein:Y2O3:1-3%.
Further, wherein:BaO:25-33%.
Further, wherein:K2O:1-3%.
Further, wherein:Na2O:4-9%.
Further, without WO3、Ta2O5。
Further, ranges of indices of refraction 1.73-1.88, Abbe number scope are 25-32.
Further, the liquidus temperature of the optical glass is less than 1100 DEG C, and λ 80 is in below 450nm, surface devitrification resistance
Can be more than B levels, internal devitrification resistance can be A levels, powder method acid-resistant stability DAFor 1 grade, powder method water-resistant stability DWFor 1
Level.
Using gas preform made of above-mentioned high-refractive and high-dispersive optical glass.
Using optical element made of above-mentioned high-refractive and high-dispersive optical glass.
Using optical instrument made of above-mentioned high-refractive and high-dispersive optical glass.
The beneficial effects of the invention are as follows:The ranges of indices of refraction of high-refractive and high-dispersive optical glass provided by the invention is
1.73-1.88, Abbe number scope are 25-32, do not contain Nb2O5, liquidus temperature is less than 1100 DEG C, and λ 80 is on below 450nm, surface
Devitrification resistance can be more than B levels, and internal devitrification resistance can be A levels, powder method acid-resistant stability DAFor 1 grade, it is steady that powder method is water-fast
Qualitative DWFor 1 grade.
Embodiment
Whole components contained by optical glass of the present invention are described more fully below, these components are all according to weight percent
Than representing.
SiO2It is the Network former oxide of glass, plays a part of building skeleton in glass.In the present invention, if
Its content is less than 20%, it is impossible to forms glass;If its content is higher than 35%, the refractive index of glass and dispersion can not reach design
It is required that.Therefore, in the present invention, SiO2Content be limited to 20-35%, more preferably 22-31%.
B2O3It is the Network former oxide of glass, in glass can be with SiO2Dissolve each other, it is common to build glass skeleton.
B2O3The liquidus temperature of glass can be effectively reduced, glass ingredient is carried out melting at low temperature, is thus favorably improved glass
Blue light transmitance.But if B2O3Content it is excessive, its coordination structure can change, and to capture in glass and exist
Free oxonium ion, can make Ti ions that the structure change unfavorable to blue light transmitance occur.Study and find through the present inventor, at this
In the glass system of invention, if B2O3The content of component is maintained in the range of 1-7%, not only can effectively reduce smelting temperature,
Also it is not easy to grab free oxygen present in glass ingredient, B simultaneously2O3Preferred content be 2-6%.
TiO2Belong to intermediate oxide in glass, its role is to improve refractive index and the dispersion of glass.In this hair
In bright, inventor is found that TiO by research2To the mechanism of glass coloration, i.e. TiO2After content increase in glass, Ti from
The ligancy and valence state of son can change, and this change can cause glass blue light transmitance to decline.Inventor is by entering one
Step research is found, if reasonably configuring B2O3, alkaline earth oxide, alkali metal oxide and rare earth oxide, can make
TiO2While content increases in glass so that Ti ions are inhibited for blue light transmitance detrimental effect, so that
The λ 80 of glass is guaranteed, while its devitrification tolerance can also meet the needs of hot pressing type technique.In the present invention, if
TiO2Content be less than 20%, the refractive index of glass will be unable to reach design object with dispersion;If TiO2Content be higher than 35%,
The devitrification resistance property of one side glass will reduce, on the other hand, as content of the Ti ions in glass ingredient increases, λ 80
Can significantly it rise.Therefore, TiO2Content is defined to 20-35%, preferred content 21-31%.
La2O3Refractive index and the dispersion of glass can be lifted as rare earth oxide.In the present invention, if its content is low
In 1%, refractive index will not reach design requirement with dispersion;If its content is higher than 10%, then the devitrification resistance property of glass will
Reduce.Therefore, in the present invention, La2O3Content be defined to 1-10%, preferred content 2-8%.
Y2O3Refractive index and the dispersion of glass, while and La can be adjusted as rare earth oxide2O3When coexisting, Ke Yiti
The devitrification resistance property of high glass.In the present invention, when its content is less than 0.5%, improvement unobvious;If content is higher than
8%, devitrification resistance property will decline.So Y2O3Content be defined to 0.5-8%, preferred content 1-3%.
ZrO2The devitrification resistance property and chemical stability of glass can be lifted, if its content is less than 0.5%, DeGrain;
If its content is higher than 6%, the liquidus temperature of glass can be significantly improved, it is unfavorable to blue light transmitance.So in the present invention,
ZrO2Content be defined to 0.5-6%, preferred content 0.5-5%.
BaO, CaO, SrO, MgO belong to alkaline earth oxide (hereinafter referred to as RO), with can adjust glass in glass
Refractive index and dispersion.In addition, RO, which is added in glass, can provide more free oxygen, the lifting to blue light transmitance is favourable.
In the present invention, BaO contents are defined to 18-38%, preferably 25-33%;CaO content is defined to 0-5%, does not add preferably;
SrO contents are defined to 0-5%, do not add preferably;Content of MgO is defined to 0-5%, does not add preferably.
Gd2O3Refractive index and the dispersion of glass can be lifted, meanwhile, a small amount of Gd2O3Component and La2O3, can be with when coexisting
Reduce the tendency towards devitrification of glass.In the present invention, when its content is higher than 8%, glass devitrification resistance penalty is on the one hand made, separately
On the one hand cost of material is caused to increase.Therefore, Gd2O3Content is defined to 0-8%, does not add preferably.
ZnO is the component arbitrarily added in the present invention, and refractive index and the dispersion of glass can be adjusted by adding in glass, may be used also
To reduce the Tg temperature of glass.But if its content more than 6%, can cause glass devitrification resistance penalty.Therefore, ZnO content limits
It is set to 0-6%, does not add preferably.
Na2O、K2O、Li2O belongs to alkali metal oxide(Hereinafter referred to as R2O).In the present invention, R2O can reduce glass
Liquidus temperature, while free oxygen can be provided.But R2O addition can not be excessive, otherwise can cause devitrification resistance property
Decline.In the present invention, Na2O content is defined to 3-10%, preferably 4-9%;K2O content is defined to 0.5-5.5%, preferably
For 1-3%;Li2O content is defined to 0-2%, does not add preferably.
Sb2O3Used in glass ingredient as fining agent, its content is defined to 0-0.1%, does not add preferably.
The performance of the optical glass of the present invention is described below:
The optical glass refractive index scope of the present invention is 1.73-1.88, and Abbe number scope is 25-32.Refractive index and Abbe
Number is by GB/T7962.11-2010 regulation method of testing measurements.
The liquidus temperature of the optical glass of the present invention is less than 1100 DEG C.Liquidus temperature is measured using Differential scanning calorimetry.
The λ 80 of the optical glass of the present invention is in below 450nm, preferably below 440nm.The λ 80 of optical glass, which is utilized, to be divided
Light photometer measurement, i.e. thickness of sample are 10mm ± 0.1mm, and using spectrophotometer measurement, λ 80 refers to that glass transmitance reaches
Corresponding wavelength when 80%, unit nm.
The surface devitrification resistance of the optical glass of the present invention can be more than B levels.Glass surface devitrification resistance energy(DCS)Take
Tests below mode is tested:
Experimental glass is cut into 30mm × 30mm × 10mm slug, and refined, then on its surface smear
B2N3Coating, temperature setting is more than the Tg temperature of glass 270 DEG C or so, and is incubated 30 minutes.Then take out and be put into heat-preservation cotton
Slow cooling.Erase B2N3Coating, crystallization spot is observed under light, and ground off crystallization spot by sample grinding machine, record crystallization spot
Depth, criterion are:
Surface illustrates that glass surface anti-crystallization ability is strong, is designated as " A " level without crystallization spot;
There is crystallization spot on surface, but Surface Crystallization spot area accounts for whole surface area below 5%, while crystallization spot depth is not
More than 0.5mm, " B " level is designated as;
There is crystallization spot on surface, but Surface Crystallization spot area accounts for whole surface area between 5-30%, or crystallization spot depth
0.8mm is not reached more than 0.5mm but, is designated as " C " level;
There is crystallization spot on surface, but Surface Crystallization spot area accounts for whole surface area more than 30%, or crystallization spot depth is
More than 0.8mm, it is designated as " D " level.
The inside devitrification resistance of the optical glass of the present invention can be A levels.Inside glass devitrification resistance can take tests below
Mode is tested:Experimental glass is cut into 30mm × 30mm × 10mm slug, is put into Muffle furnace, temperature setting is glass
More than the Tg temperature of glass 270 DEG C or so, and 30 minutes are incubated, then take out and be put into Slow cooling in heat-preservation cotton.To obtained sample
Product are polished, and are put into test under microscope, and criterion is:
The crystallization particle being visible by naked eyes, it is designated as " A " level;
Visually visible crystallization particle, quantity is few and scattered, is designated as " B " level;
Visually visible larger scattered or comparatively dense and small crystallization particle, are designated as " C " level;
Crystallization particle is larger and intensive, is designated as " D " level;
The complete crystallization devitrification of glass, is designated as " E " level.
The powder method acid-resistant stability of the optical glass of the present invention(DA)For 1 grade;Powder method water-resistant stability(DW)For 1 grade.
Powder method acid-resistant stability(DA)And powder method water-resistant stability(DW)Measured according to GB/T17129 prescriptive procedures.
The present invention also provides a kind of optical precast product and optical element, by above-mentioned optical glass according to those skilled in the art
Well known method is formed.Because described optical glass has high index of refraction and high dispersion, therefore the optical element
With high index of refraction and high dispersion, the equipment such as digital camera, digital camera, camera cell phone are can apply to.
Embodiment
In order to further appreciate that technical scheme, the embodiment of optical glass of the present invention will now be described.Should
It is noted that these embodiments do not limit the scope of the present invention.
The optical glass shown in table 1- tables 3(Embodiment 1-25)It is by according to each embodiment shown in table 1- tables 3
Ratio is weighed and hybrid optical glass common raw material(Such as oxide, hydroxide, carbonate, nitrate), mixing is former
Material is placed in platinum crucible, is melted in certain temperature, and after melting, clarify, stirring and being homogenized, obtain not gas
Bubble and the homogeneous melt glass without undissolved material, by this melten glass in mould casting mold and anneal form.
1-25 of embodiment of the present invention composition and refractive index(nd), Abbe number(vd), surface anti-crystallization ability, internal anti-analysis
Brilliant ability, λ 80, liquidus temperature(LT)And powder method acid-resistant stability(DA), powder method water-resistant stability(DW)Result together
Represented in table 1- tables 3.Holding temperature when holding temperature 1 in table 1- tables 3 is test internal devitrification resistance energy, holding temperature
2 holding temperature when being test surfaces devitrification resistance energy, in these tables, the composition of each component is represented with weight %.
Table 1
Table 2
Table 3
。
Claims (18)
1. high-refractive and high-dispersive optical glass, it is characterised in that represented, contained with weight percent oxide:SiO2:20-
35%th, B2O3:1-7%, TiO2:20-35%, La2O3:1-10%, ZrO2:0.5-6%, Y2O3:0.5-8%, BaO:18-38%,
K2O:0.5-5.5%, Na2O:3-10%, Nb is not contained2O5。
2. high-refractive and high-dispersive optical glass as claimed in claim 1, it is characterised in that total content of the oxide exists
More than 95%.
3. high-refractive and high-dispersive optical glass as claimed in claim 1, it is characterised in that also contain Gd2O3:0-8%, ZnO:
0-6%, CaO:0-5%, SrO:0-5%, Li2O:0-2%, MgO:0-5%.
4. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:SiO2:22-31%.
5. the optical glass as described in claim 1,2 or 3, it is characterised in that wherein:B2O3:2-6%.
6. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:TiO2:21-31%.
7. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:La2O3:2-8%.
8. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:ZrO2:0.5-5%.
9. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:Y2O3:1-3%.
10. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:BaO:25-
33%.
11. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:K2O:1-3%.
12. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that wherein:Na2O:4-9%.
13. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that without WO3、Ta2O5。
14. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that ranges of indices of refraction is
1.73-1.88, Abbe number scope are 25-32.
15. the high-refractive and high-dispersive optical glass as described in claim 1,2 or 3, it is characterised in that the liquid of the optical glass
Phase temperature is less than 1100 DEG C, and it is 10mm ± 0.1mm to take glass sample thickness, using spectrophotometer measurement, λ 80 450nm with
Under, surface devitrification resistance can be more than B levels, and internal devitrification resistance can be A levels, powder method acid-resistant stability DAFor 1 grade, powder method
Water-resistant stability DWFor 1 grade.
16. using gas preform made of the high-refractive and high-dispersive optical glass described in claim 1,2 or 3.
17. using optical element made of the high-refractive and high-dispersive optical glass described in claim 1,2 or 3.
18. using optical instrument made of the high-refractive and high-dispersive optical glass described in claim 1,2 or 3.
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CN105461222A (en) * | 2016-01-12 | 2016-04-06 | 成都光明光电有限责任公司 | High-refraction high-dispersion optical glass |
JP7076981B2 (en) | 2017-10-25 | 2022-05-30 | キヤノン株式会社 | Manufacturing method of optical glass, optical element, optical equipment and optical glass |
CN109502964B (en) * | 2018-12-07 | 2023-03-28 | 成都光明光电股份有限公司 | Heavy lanthanum flint glass and prefabricated member, optical element and optical instrument thereof |
CN109851217B (en) * | 2018-12-07 | 2022-03-08 | 成都光明光电股份有限公司 | Heavy lanthanum flint glass and prefabricated member, optical element and optical instrument thereof |
CN113526868A (en) * | 2021-07-06 | 2021-10-22 | 苏州光大光电科技有限公司 | Weather-resistant optical glass and production process thereof |
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CN1252391A (en) * | 1998-10-19 | 2000-05-10 | 肖特玻璃厂 | Lead-free optic glass |
JP2004155639A (en) * | 2001-11-14 | 2004-06-03 | Hoya Corp | Optical glass, glass material for press molding, optical element, and methods of manufacturing them |
CN1840494A (en) * | 2005-02-21 | 2006-10-04 | Hoya株式会社 | Optical glass, glass gob for press-molding, optical part, process for producing glass shaped material and process for producing optical part |
WO2013180082A1 (en) * | 2012-05-28 | 2013-12-05 | 株式会社オハラ | Optical glass |
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CN1252391A (en) * | 1998-10-19 | 2000-05-10 | 肖特玻璃厂 | Lead-free optic glass |
JP2004155639A (en) * | 2001-11-14 | 2004-06-03 | Hoya Corp | Optical glass, glass material for press molding, optical element, and methods of manufacturing them |
CN1840494A (en) * | 2005-02-21 | 2006-10-04 | Hoya株式会社 | Optical glass, glass gob for press-molding, optical part, process for producing glass shaped material and process for producing optical part |
WO2013180082A1 (en) * | 2012-05-28 | 2013-12-05 | 株式会社オハラ | Optical glass |
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